Low‐velocity impact response and post‐impact assessment of self‐healing composites with different stacking configurations of core–shell nanofibers

Cai, Haopeng; Gan, Yu; Chen, Boxue; Mao, Chi; Gao, Lihua; Li, Mengzhi; Wang, Kuo

doi:10.1002/pc.27925

Cited by 2 publications

(1 citation statement)

References 49 publications

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“…Cai et al investigated the post‐impact self‐healing efficiency of polyacrylonitrile core–shell nanofibers interleaved carbon composites. Different stacking configurations were employed for that purpose to report the highest recovery rate of 80% of the pre‐impact flexural strength 14 . In a similar vein, Wan et al confirmed the self‐healing capacity of CNT reinforced core–shell electrospun nanofibre interleaved composites 15 .…”

Section: Introductionmentioning

confidence: 93%

Electrospun nanofiber interleaving through double infusion method to induce pseudo‐ductile damage resistance response in carbon/epoxy composites

Shakil,

Hassan,

Yahya

et al. 2024

Polymer Composites

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Carbon composites are susceptible to invisible damage development such as matrix cracking, fiber kinking, and interfacial debonding upon external transverse loading. These incipient damages may interact to evolve into life‐limiting delamination propagating both in in‐plane and transverse directions. This study addressed that by interleaving carbon/epoxy composites with electrospun nylon 6 nanofibers adopting a double infusion method. Damage resistance results showed that the optimum nanofiber areal weight (17.35 g/m2) offered a 27% improvement in specific total toughness. The emergence of pseudo‐ductility substantially enhanced the plastic toughness (46.15%) of interleaved composites. The load required for initial matrix cracking was 65.49% higher, and number of matrix cracking events was suppressed by 84.11% at the optimum areal weight of interleave. Fractography revealed frequent interlaminar crossings and delamination crack bridging as two major toughness mechanisms. Both the external damage area and delaminated area increased with increment in nanofiber areal weight.Highlights Electrospun nanofibre interleaved carbon/epoxy composites were fabricated through a double infusion method to characterize damage resistance. Acoustic data of matrix cracking was rationalized to show the effectiveness of nanofiber interleaves in suppressing this damage type. Microstructural factors and mechanisms contributing to the improved toughness of optimally interleaved composites were identified. External damage/delaminated areas of interleaved composites were correlated with nanofiber areal weights.

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Section: Introductionmentioning

confidence: 93%

Electrospun nanofiber interleaving through double infusion method to induce pseudo‐ductile damage resistance response in carbon/epoxy composites

Shakil,

Hassan,

Yahya

et al. 2024

Polymer Composites

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Impact resistance optimization of composite laminates based on variable‐fidelity surrogate model

Liu,

Lu,

Zhang

et al. 2024

Polymer Composites

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To improve the impact resistance of composite materials, this study introduces an efficient global optimization framework based on a multi‐fidelity surrogate model to optimize the layup sequence of laminates. Numerical simulation models are constructed utilizing Hashin and Puck failure criteria to provide a few time‐consuming high‐fidelity samples and a multitude of inexpensive low‐fidelity samples. The traditional genetic algorithm has been improved in terms of encoding mechanisms, genetic operators, genetic probabilities, algorithm structure, and the recognition of constraint conditions. The translation propagation algorithm based on optimal Latin hypercube sampling is used to generate initial sample points and improve the quality of space filling. An efficient global optimization framework for time‐consuming simulation problems is established by combining the Hierarchical Kriging surrogate model and multi‐fidelity expectation improved addition criterion to seek the optimal layup sequence of composites when the impact resistance of unconventional layup laminates is maximized. The optimized laminate shows a significant increase in impact resistance, evidenced by a 32.5% increase in peak impact contact force and an 18.01% decrease in the total delamination damage area. Analysis of the impact damage area reveals that post‐optimization, the laminate deforms less under impact load, exhibiting more directions of damage spread and an enhanced load‐bearing capacity.Highlights An improved DNA genetic algorithm is proposed in terms of encoding mechanisms, genetic operators, and algorithm structure. Numerical simulation models are constructed utilizing Hashin and Puck failure criteria to provide high‐fidelity samples. An efficient global optimization framework for time‐consuming simulation problems is established by combining the Hierarchical Kriging surrogate model. The mechanical response and damage mechanism of the original and optimized laminates under low‐velocity impact are analyzed.

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Low‐velocity impact response and post‐impact assessment of self‐healing composites with different stacking configurations of core–shell nanofibers

Cited by 2 publications

References 49 publications

Electrospun nanofiber interleaving through double infusion method to induce pseudo‐ductile damage resistance response in carbon/epoxy composites

Electrospun nanofiber interleaving through double infusion method to induce pseudo‐ductile damage resistance response in carbon/epoxy composites

Impact resistance optimization of composite laminates based on variable‐fidelity surrogate model

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